88 lines
3.2 KiB
Python
88 lines
3.2 KiB
Python
import pandas as pd
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import numpy as np
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from tensorflow.keras.models import Sequential
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from tensorflow.keras.layers import Dense
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from sklearn.preprocessing import LabelEncoder
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from sklearn.metrics import accuracy_score
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from keras.utils import np_utils
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from tensorflow import keras
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import mlflow
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import sys
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mlflow.set_experiment("s444517")
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# reading data
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def read_data():
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all_data = []
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for name in ['train', 'test', 'validate']:
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all_data.append(pd.read_csv(f'apps_{name}.csv', header=0))
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return all_data
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def data_prep():
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train_set, test_set, validate_set = read_data()
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train_set = train_set.drop(columns=["Unnamed: 0"])
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test_set = test_set.drop(columns=["Unnamed: 0"])
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validate_set = validate_set.drop(columns=["Unnamed: 0"])
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numeric_columns = ["Rating", "Reviews", "Installs", "Price", "Genres_numeric_value"]
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# train set set-up
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x_train_set = train_set[numeric_columns]
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y_train_set = train_set["Category"]
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encoder = LabelEncoder()
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encoder.fit(y_train_set)
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encoded_Y = encoder.transform(y_train_set)
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dummy_y = np_utils.to_categorical(encoded_Y)
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# validation set set-up
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x_validate_set = validate_set[numeric_columns]
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y_validate_set = validate_set["Category"]
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encoder = LabelEncoder()
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encoder.fit(y_validate_set)
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encoded_Yv = encoder.transform(y_validate_set)
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dummy_yv = np_utils.to_categorical(encoded_Yv)
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#test set set-up
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x_test_set = test_set[numeric_columns]
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y_test_set = test_set["Category"]
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y_class_names = train_set["Category"].unique()
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encoder = LabelEncoder()
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encoder.fit(y_test_set)
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encoded_Ytt = encoder.transform(y_test_set)
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dummy_ytt = np_utils.to_categorical(encoded_Ytt)
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return x_train_set, dummy_y, x_validate_set, dummy_yv, x_test_set, y_test_set, y_class_names
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with mlflow.start_run():
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epoch = int(sys.argv[1]) if len(sys.argv) > 1 else 200
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first_activation_funct = int(sys.argv[2]) if len(sys.argv) > 2 else "relu"
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second_activation_funct = int(sys.argv[3]) if len(sys.argv) > 3 else "softmax"
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x_train_set, dummy_y, x_validate_set, dummy_yv, x_test_set, y_test_set, y_class_names = data_prep()
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number_of_classes = 33
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number_of_features = 5
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model = Sequential()
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model.add(Dense(number_of_classes, activation=first_activation_funct))
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model.add(Dense(number_of_classes, activation=second_activation_funct,input_dim=number_of_features))
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model.compile(optimizer='adam', loss='categorical_crossentropy', metrics=['accuracy', 'categorical_accuracy'])
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model.fit(x_train_set, dummy_y, epochs=epoch, validation_data=(x_validate_set, dummy_yv))
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#model.save("my_model/")
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#model predictions
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yhat = model.predict(x_test_set)
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y_true = []
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y_pred = []
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for numerator, single_pred in enumerate(yhat):
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y_true.append(sorted(y_class_names)[np.argmax(single_pred)])
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y_pred.append(y_test_set[numerator])
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mlflow.log_param("epoch", epoch)
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mlflow.log_param("1st_activation_funct", first_activation_funct)
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mlflow.log_param("2nd_activation_funct", second_activation_funct)
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#mlflow.keras.log_model(model, 'my_model')
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mlflow.keras.save_model(model, "my_model")
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mlflow.log_metric("accuracy", accuracy_score(y_true, y_pred))
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